Computational Fluid Dynamics Study of Magnus Force on an Axis-Symmetric, Disk-Type AUV with Symmetric Propulsion

Chen, Chen-Wei; Yong, Jiongmin

doi:10.3390/sym11030397

Cited by 8 publications

(4 citation statements)

References 15 publications

(29 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Computational fluid dynamics (CFD) is an important basis for erosion research, and many results on erosion are based on CFD. Chen [5,6] used CFD software to analyze the gas-liquid two-phase flow of an underwater hovering device, and the fluid structure change law was found after the hovering device entered the water. Haider et al [7] and Wang et al [8] used CFD and finite element to track the particles after erosion, and obtained the wall rebound model of the particles in complex geometric shapes, which would be helpful for future erosion research.…”

Section: Introductionmentioning

confidence: 99%

Solid Particle Erosion Area of Rotor Blades: Application on Small-Size Unmanned Helicopters

et al. 2021

View full text Add to dashboard Cite

Rotor blades play an important role in unmanned helicopters, and it is of great significance to study the erosion of rotor blades. In this study, titanium alloy (Ti-4Al-1.5Mn) was used as the helicopter rotor blades’ surface material. The commercial software Ansys-Fluent 18.0 was mainly used to study the erosion of solid particles on the helicopter rotor blades. The moving mesh method and the discrete phase method (DPM) were used to construct an erosion model of the blades at different speeds (500, 1000, or 2000 rpm), and at different particle mass flow rates (0.5, 1, or 1.5 kg/s). The results show that the erosion of helicopter blades is mainly observed at the leading edge and at the tip of the blades. At different particle mass flow rates, greater particle mass flow rates lead to greater DPM erosion rates. As the blade speed increases, the maximum DPM erosion rate decreases, but the severely eroded area increases. Finally, the values of the severely eroded area of the helicopter rotor blades and the ratios of the severely eroded area growth are obtained through the image processing method.

show abstract

Section: Introductionmentioning

confidence: 99%

Solid Particle Erosion Area of Rotor Blades: Application on Small-Size Unmanned Helicopters

et al. 2021

View full text Add to dashboard Cite

show abstract

“…As second challenge mentioned, complex behavior from collision of particles are formed and will affect on polymer motion in nano channel. Numerical simulation is a promising tool for understanding the complex behavior of polymer chains 29 . Clearly, the particle methods for simulation are able to show more details.…”

Section: Introductionmentioning

confidence: 99%

Simulation of nano elastic polymer chain displacement under pressure gradient/electroosmotic flow with the target of less dispersion of transition

Zakeri

Lee

2021

Sci Rep

View full text Add to dashboard Cite

Since non-scattering transfer of polymer chain in nanochannel is one of the important issue in biology, in this research, the behavior study of a long polymer chain in the nanofluid in two modes of free motion and restricted motion (fixed two ends) under two different forces including constant force (pressure gradient (PG)) and variable force (electroosmotic force (EOF)) has been investigated using dissipative particle dynamics (DPD) method. Our aim is that displacement of polymer chain carries out with less dispersion. Initially, without the presence of polymer, the results have been validated in a nanochannel by analytical results for both cases (PG, EOF) with an error of less than 10%. Then, assuming 50 beads of polymer chain, the polymer chain motion in free motion and fixed two ends modes has been examined by different spring coefficients between beads and different forces including PG (0.01 DPD unite) and EOF (zeta potential = − 25 mV, electric field = 250 V/mm, kh parameter = 8). The results show that in free polymer motion-PG mode, by increasing 1.6 times of spring coefficient of the polymer, a 40% reduction in transition of polymer is achieved, which high dispersion of polymer chain is resulted for this mode. In the EOF, the spring coefficient has a slight effect on transferring of polymer and also, EOF moves the polymer chain with extremely low polymer chain scattering. Also, for fixed two ends-PG mode, a 36% reduction in displacement is achieved and in the same way, in EOF almost 39% declining in displacement is resulted by enhancing the spring coefficients. The results have developed to 25 and 100 beads which less dispersion of polymer chain transfer for free polymer chain-EOF is reported again for both circumstances and for restricted polymer chain state in two PG and EOF modes, less differences are reported for two cases. The results show that the EOF has the benefit of low dispersion for free polymer chain transfer, also, almost equal displacement for restricted polymer chain mode is observed for both cases.

show abstract

“…Such simulation methods have been successfully applied to different nano-scale flow problems. Researches have used different numerical simulation methods such as computational fluid dynamics [5][6][7], molecular dynamics [8], Langevin dynamics [9,10], and Brownian dynamics [11] to study prediction of polymer chains behavior in fluid flows. Based on the Lagrangian methods such as Molecular Dynamics [12][13][14][15], lattice Boltzmann method [16,17] or smoothed particle hydrodynamics method [18][19][20][21], the dissipative particle dynamics (DPD) method is a mesoscopic method [12,13,22] which has been vastly used in micro/nano-scale simulations.…”

Section: Introductionmentioning

confidence: 99%

Investigation of Magneto Hydro-Dynamics Effects on a Polymer Chain Transfer in Micro-Channel Using Dissipative Particle Dynamics Method

et al. 2020

View full text Add to dashboard Cite

In this paper, the effect of Magneto Hydro-Dynamics (MHD) on a polymer chain in the micro channel is studied by employing the Dissipative Particle Dynamics simulation (DPD) method. First, in a simple symmetric micro-channel, the results are evaluated and validated for different values of Hartmann (Ha) Number. The difference between the simulation and analytical solution is below 10%. Then, two types of polymer chain including short and long polymer chain are examined in the channel and the effective parameters such as Ha number, the harmony bond coefficient or spring constant (K), and the length of the polymer chain (N) are studied in the MHD flow. It is shown that by increasing harmony bond constant to 10 times with Ha = 20, the reduction of about 80% in radius of gyration squared, and half in polymer length compared to Ha = 1 would occur for both test cases. For short and long length of polymer, proper transfer of a polymer chain through MHD particles flow is observed with less perturbations (80%) and faster polymer transfer in the symmetric micro-channel.

show abstract

Computational Fluid Dynamics Study of Magnus Force on an Axis-Symmetric, Disk-Type AUV with Symmetric Propulsion

Cited by 8 publications

References 15 publications

Solid Particle Erosion Area of Rotor Blades: Application on Small-Size Unmanned Helicopters

Solid Particle Erosion Area of Rotor Blades: Application on Small-Size Unmanned Helicopters

Simulation of nano elastic polymer chain displacement under pressure gradient/electroosmotic flow with the target of less dispersion of transition

Investigation of Magneto Hydro-Dynamics Effects on a Polymer Chain Transfer in Micro-Channel Using Dissipative Particle Dynamics Method

Contact Info

Product

Resources

About